First Claim

a receiver portion, formed of plural electrical components, said plural magnetic receiving antennas, and a power output part, wherein at least one of said electrical components is formed using a mechanical machining process which creates mechanical features forming said plural electrical components of 1 μm or less.

25 Claims

1. A wireless power receiver device, comprising:

a receiver portion, formed of plural electrical components, said plural magnetic receiving antennas, and a power output part, wherein at least one of said electrical components is formed using a mechanical machining process which creates mechanical features forming said plural electrical components of 1 μm or less.

2. A receiver as in claim 1, wherein said feature includes an inductor.

3. A receiver as in claim 1, wherein said feature includes a capacitor.

4. A receiver as in claim 1, wherein said feature includes a magnet.

5. A receiver as in claim 4, wherein said magnet is mounted for movement under influence from an alternating magnetic field.

6. A receiver as in claim 5, wherein said plural components include an array of moving magnets.

7. A receiver as in claim 6, further comprising a single inductance coil shared among said array of magnets.

8. A receiver as in claim 5, wherein said magnet is radially symmetrical.

9. A wireless receiver, comprising:

a first portion, including a movable magnet, located in an location to receive an alternating magnetic field, a magnetic part, adjacent said movable magnet, and in a location where movement of the movable magnet creates energy; and

10. A receiver as in claim 9, further comprising a coil, and wherein said coil and said movable magnet are each less than 10 μm in overall size.

11. A receiver as in claim 9, wherein said magnet is smaller than 2 cm3.

12. A receiver as in claim 9, wherein there are a plurality of magnets arranged such that their outputs sum to create a power output.

13. A receiver as in claim 12, wherein said plurality of magnets collectively occupy a space of 2 cm3 or less.

14. A receiver as in claim 10, wherein said plurality of magnets are arranged in a two-dimensional array.

15. A receiver as in claim 9, wherein said moving magnet includes a torsion part, and a spring, the moving magnet moving under influence of the magnetic field, and further comprising at least one induction coil, located adjacent to moving magnet, and converting kinetic energy into electrical energy.

16. A receiver as in claim 9, wherein said magnet is radially symmetrical.

17. A receiver as in claim 12, where each said magnet is radially symmetrical.

18. A method of receiving power, comprising:

locating an array of movable magnets in a location to receive an alternating magnetic field;

using said movement of the moving magnet to create energy; and

using said energy created by said moving magnet to power a load in a portable electronic device.

19. A method as in claim 18, further comprising a single coil shared among said array of movable magnets.

20. A method as in claim 19, wherein said coil and said moving magnet are each less than 10 μm in overall size.

21. A receiver as in claim 18, wherein each said magnet is smaller than 2 cm3.

22. A receiver as in claim 18, wherein said plurality of magnets are arranged in a two-dimensional array.

23. A wireless power transmitting device, comprising:

a first portion, formed of a magnetic generator, and a high frequency generation system, having a number of components, wherein at least one of said components is formed using a mechanical machining process which creates features of 1 μm or less.

1 Specification

It is desirable to transfer electrical energy from a source to a destination without the use of wires to guide the electromagnetic fields. A difficulty of previous attempts has been low efficiency together with an inadequate amount of delivered power.

The system can use transmit and receiving antennas that are preferably resonant antennas, which are substantially resonant with a specified transmit or receive frequency, e.g., they have values that bring them within 5%, 10%, 15% or 20% of resonance. The antenna(s) are preferably of a small size to allow it to fit into a mobile, handheld device where the available space for the antenna may be limited. An efficient power transfer may be carried out between two antennas by storing energy in the near field of the transmitting antenna, rather than sending the energy into free space in the form of a travelling electromagnetic wave. Antennas with high quality factors can be used. Two high-Q antennas are placed such that they react similarly to a loosely coupled transformer, with one antenna inducing power into the other. The antennas preferably have Qs that are greater than 1000.

SUMMARY

The present application describes transfer of energy from a power source to a power destination via electromagnetic field coupling. An embodiment uses magneto-mechanical systems for receiving the power. Embodiments describe techniques for using micro-electro-mechanical systems or MEMS for forming the magneto mechanical system.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects will now be described in detail with reference to the accompanying drawings, wherein:

FIG. 1 shows a block diagram of a magnetic wave based wireless power transmission system;

FIG. 2 illustrates an MMS embodiment;

FIG. 3 illustrates the flow of energy using an MMS embodiment;

FIG. 4 shows a block diagram; and

FIG. 5 shows an array of MMS devices

DETAILED DESCRIPTION

A basic embodiment is shown in FIG. 1. A power transmitter assembly 100 receives power from a source, for example, an AC plug 102. A frequency generator 104 is used to couple the energy to an antenna 110, here a resonant antenna. The antenna 110 includes an inductive loop 111, which is inductively coupled to a high Q resonant antenna part 112. The resonant antenna includes a number N of coil loops 113 each loop having a radius R<sub>A</sub>. A capacitor 114, here shown as a variable capacitor, is in series with the coil 113, forming a resonant loop. In the embodiment, the capacitor is a totally separate structure from the coil, but in certain embodiments, the self capacitance of the wire forming the coil can form the capacitance 114.

The frequency generator 104 can be preferably tuned to the antenna 110, and also selected for FCC compliance.

This embodiment uses a multidirectional antenna. 115 shows the energy as output in all directions. The antenna 100 is non-radiative, in the sense that much of the output of the antenna is not electromagnetic radiating energy, but is rather a magnetic field which is more stationary. Of course, part of the output from the antenna will in fact radiate.

Another embodiment may use a radiative antenna.

A receiver 150 includes a receiving antenna 155 placed a distance D away from the transmitting antenna 110. The receiving antenna is similarly a high Q resonant coil antenna 151 having a coil part and capacitor, coupled to an inductive coupling loop 152. The output of the coupling loop 152 is rectified in a rectifier 160, and applied to a load. That load can be any type of load, for example a resistive load such as a light bulb, or an electronic device load such as an electrical appliance, a computer, a rechargeable battery, a music player or an automobile.

The energy can be transferred through either electrical field coupling or magnetic field coupling, although magnetic field coupling is predominantly described herein as an embodiment.

Electrical field coupling provides an inductively loaded electrical dipole that is an open capacitor or dielectric disk. Extraneous objects may provide a relatively strong influence on electric field coupling. Magnetic field coupling may be preferred, since extraneous objects in a magnetic field have the same magnetic properties as “empty” space.

The embodiment describes a magnetic field coupling using a capacitively loaded magnetic dipole. Such a dipole is formed of a wire loop forming at least one loop or turn of a coil, in series with a capacitor that electrically loads the antenna into a resonant state.

An embodiment forms a receiver from a magneto mechanical system. One embodiment uses Micro Electro-Mechanical Systems (MEMS) to exploit their gyromagnetic properties. An embodiment uses materials can be used to form these magneto-mechanical systems.

MEMS is used herein to refer to any mechanical structure that forms a mechanical structure of a size of micrometers or less, e.g, using semiconductor processing techniques. According to an embodiment, MEMS is used to form switches, inductors, variable capacitors, reconfigurable antennas and antenna parts, etc.

An embodiment imitates the gyromagnetic high-Q resonance effect of YIG material, e.g. at lower frequencies. This may be used for non-radiative wireless energy transfer.

Micro magneto-mechanical systems may be formed of a plurality of micro permanent magnets each individually rotatable on an axis. The plurality may be an array or medium, of structures.

A first embodiment uses a Compass type MMS device. A second embodiment uses a Torsion type MMS device.

The compass-type MMS has a medium formed of micro-magnets that are biased (saturated) by applying a static magnetic field H<sub>0</sub>. The system exhibits a ferromagnetic resonance at a characteristic frequency defined by its magnetization M<sub>0 </sub>and the inertial moment I<sub>m </sub>of the micromachined magnets and H<sub>0</sub>.

The embodiment shown in FIG. 2 uses a torsion-type MMS with multiple micromagnets each supported by a torsional beam. This embodiment does not include a static magnetic field requirement. The system can be tuned to exhibit a ferromagnetic resonance at a characteristic frequency defined by the magnetization M<sub>0 </sub>and the inertial moment I<sub>m </sub>of the micro-magnets, and the spring constant of the torsional beam.

FIG. 2 shows the basic principle of a torsion type magneto mechanical system. An induction coil 200 is used to convert the kinetic energy into electrical energy. This induction coil 200 is under the influence of an external alternating magnetic field 205. The applied magnetic dipole moment causes a moment of:

<FORM>T(t)=M(t)×B(t)</FORM>

This causes a magnetically oscillating bar magnet in producing the voltage in the surrounding coil 200 using the dynamo principle. A spiral spring 215 may represent the torsional beam.

In the context of power transmission, compass-type or torsion-type MEMS may be considered as

a Ferrite that magnifies the alternating magnetic flux through the antenna wire loop (coil) preferably at the resonance frequency,

a. high-Q resonator coupled to the transmitter via the magnetic field (the driving force is Lorentz force in contrast to L-C-type resonators based on the induction law, and/or

a dynamo remotely driven by the transmitter through the magnetic field converting kinetic energy into electric energy.

In an embodiment, the beam 210 is radially symmetrical, e.g., sphere or disk shaped.

A wireless energy transfer system with a ‘dynamo’ receiver can carry out a system according to the diagram of FIG. 3. The transmitter 300 converts electric energy 302 to magnetic energy 304. The magnetic energy 304 is received in a dynamo receiver and converted to kinetic energy 306. The kinetic energy is converted back to electric energy and used at the receiver.

FIG. 4 shows an embodiment where a transmit loop 400 creates a magnetic field shown generally as 405.

A dynamo receiver 410 remains within the area of the magnetic field 405. The dynamo receiver includes a moving magnet 415. That moving magnet may use a non resonant ferromagnetic system, resonant gyro magnetism, and/or a magneto mechanical system e.g. a resonant system. According to an embodiment, the magnet has no dimension that is larger than 10 um, more preferably none less than 5 um or 1 um.

The output of the moving magnet creates a magnified magnetic flux 420. The flux can be expressed as Φ(t).

One problem noted in using the magnetic flux in such a moving is that the high amount of stored energy/reactive power in these magnets.

According to an embodiment, an array of micromechanical structures, is used as shown in FIG. 5. The array can be of any shape, e.g., a two dimensional array or a one dimensional array, or a circular array. In an embodiment, the entire array fits within a volume of approximately 2 cm<sup>3</sup>. A number of micromechanical structures such as 500, 501 is arranged in this array.

FIG. 5 shows the array 500, 501 of mechanically oscillating magnets and a single coil 505 wound around that array. Movement of the magnets transforms the kinetic oscillatory energy into electrical energy. The system exhibits a resonance that is defined by the mechanical parameters of each elementary oscillator. An external capacitor 510 added to the pick-up coil 505 is used to maintain the LC constant of this system at resonance. The power output is illustrated as a summation of all the outputs of all the magnets at 520.

The above has described using MEMS to form an array of micro sized magnetomechanical systems. Other kinds of miniature magnets, however, can alternatively be used for this purpose.

Although only a few embodiments have been disclosed in detail above, other embodiments are possible and the inventors intend these to be encompassed within this specification. The specification describes specific examples to accomplish ˜ more general goal that may be accomplished in another way. This disclosure is intended to be exemplary, and the claims are intended to cover any modification or alternative which might be predictable to a person having ordinary skill in the art. For example, other sizes, materials and connections can be used. Although the coupling part of some embodiments of the antenna is shown as a single loop of wire, it should be understood that this coupling part can have multiple wire loops. Other embodiments may use similar principles of the embodiments and are equally applicable to primarily electrostatic and/or electrodynamic field coupling as well. In general, an electric field can be used in place of the magnetic field, as the primary coupling mechanism.

Also, the inventors intend that only those claims which use the-words “means for” are intended to be interpreted under 35 USC 112, sixth paragraph. Moreover, no limitations from the specification are intended to be read into any claims, unless those limitations are expressly included in the claims.

Where a specific numerical value is mentioned herein, it should be considered that the value may be increased or decreased by 20%, while still staying within the teachings of the present application, unless some different range is specifically mentioned. Where a specified logical sense is used, the opposite logical sense is also intended to be encompassed.